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Journal articles on the topic 'Radiation Damping'

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Published: 4 June 2021
Last updated: 1 February 2022

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1

Clarkson, B. L., and K. T. Brown. "Acoustic Radiation Damping." Journal of Vibration and Acoustics 107, no. 4 (October 1, 1985): 357–60. http://dx.doi.org/10.1115/1.3269272.

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2

Sz�ntay, Csaba, and �d�m Demeter. "Radiation damping diagnostics." Concepts in Magnetic Resonance 11, no. 3 (1999): 121–45. http://dx.doi.org/10.1002/(sici)1099-0534(1999)11:3<121::aid-cmr2>3.0.co;2-z.

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3

Blake, Paul R., and Michael F. Summers. "NOESY-1--echo spectroscopy with eliminated radiation damping radiation damping." Journal of Magnetic Resonance (1969) 86, no. 3 (February 1990): 622–25. http://dx.doi.org/10.1016/0022-2364(90)90040-g.

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4

Shishmarev, Dmitry, and Gottfried Otting. "Radiation damping on cryoprobes." Journal of Magnetic Resonance 213, no. 1 (December 2011): 76–81. http://dx.doi.org/10.1016/j.jmr.2011.08.040.

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5

Mendes, A. C. R., C. Neves, W. Oliveira, and F. I. Takakura. "Supersymmetrization of radiation damping." Journal of Physics A: Mathematical and General 38, no. 42 (October 5, 2005): 9387–94. http://dx.doi.org/10.1088/0305-4470/38/42/015.

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6

Augustine, M. P. "Transient properties of radiation damping." Progress in Nuclear Magnetic Resonance Spectroscopy 40, no. 2 (February 2002): 111–50. http://dx.doi.org/10.1016/s0079-6565(01)00037-1.

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7

Khitrin, A. K., and Alexej Jerschow. "Simple suppression of radiation damping." Journal of Magnetic Resonance 225 (December 2012): 14–16. http://dx.doi.org/10.1016/j.jmr.2012.09.010.

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8

Chicone, C., S. M. Kopeikin, B. Mashhoon, and D. G. Retzloff. "Delay equations and radiation damping." Physics Letters A 285, no. 1-2 (June 2001): 17–26. http://dx.doi.org/10.1016/s0375-9601(01)00327-9.

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9

Lin‐Liu, Y. R., H. Ikezi, and T. Ohkawa. "Radiation damping and resonance scattering." American Journal of Physics 56, no. 4 (April 1988): 373. http://dx.doi.org/10.1119/1.15616.

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10

Zhou, Jinyuan, Susumu Mori, and Peter C. M. van Zijl. "FAIR excluding radiation damping (FAIRER)." Magnetic Resonance in Medicine 40, no. 5 (November 1998): 712–19. http://dx.doi.org/10.1002/mrm.1910400511.

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11

Barone, P. M. V. B., and A. O. Caldeira. "Quantum mechanics of radiation damping." Physical Review A 43, no. 1 (January 1, 1991): 57–63. http://dx.doi.org/10.1103/physreva.43.57.

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12

Aguiar, C. E., and F. A. Barone. "Rutherford scattering with radiation damping." American Journal of Physics 77, no. 4 (April 2009): 344–48. http://dx.doi.org/10.1119/1.3065026.

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13

Pradhan, Anil K., and Hong Lin Zhang. "Radiation damping of autoionizing resonances." Journal of Physics B: Atomic, Molecular and Optical Physics 30, no. 17 (September 14, 1997): L571—L579. http://dx.doi.org/10.1088/0953-4075/30/17/004.

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14

Klepikov, N. P. "Radiation damping forces and radiation from charged particles." Uspekhi Fizicheskih Nauk 146, no. 6 (1985): 317. http://dx.doi.org/10.3367/ufnr.0146.198506e.0317.

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15

Klepikov, N. P. "Radiation damping forces and radiation from charged particles." Soviet Physics Uspekhi 28, no. 6 (June 30, 1985): 506–20. http://dx.doi.org/10.1070/pu1985v028n06abeh005205.

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16

Ambrosini, Ricardo Daniel. "Material damping vs. radiation damping in soil–structure interaction analysis." Computers and Geotechnics 33, no. 2 (March 2006): 86–92. http://dx.doi.org/10.1016/j.compgeo.2006.03.001.

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17

EFREMOV, G. F., V. V. SHARKOV, and D. V. KRUPENNIKOV. "NONDIVERGENT STATISTICAL QUANTUM ELECTRODYNAMICS." International Journal of Bifurcation and Chaos 18, no. 09 (September 2008): 2817–24. http://dx.doi.org/10.1142/s0218127408022056.

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Quantum space-time nonlocality, i.e. retardation of the interaction between an electron and its own radiation field at distances about the Compton wavelength, is established. By taking into account a finite variance of electron-coordinate increment in the intrinsic coordinate system, the radiative damping coefficient is obtained as a divergence-free function of frequency that is not subject to the well-known paradoxes of the classical theory of radiative damping. A relation between radiative damping and the electromagnetic mass of the electron is found.
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18

Andreev, Pavel A. "NLSE for quantum plasmas with the radiation damping." Modern Physics Letters B 30, no. 13 (May 18, 2016): 1650180. http://dx.doi.org/10.1142/s0217984916501803.

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We consider contribution of the radiation damping in the quantum hydrodynamic (QHD) equations for spinless particles. We discuss possibility of obtaining corresponding nonlinear Schrödinger equation (NLSE) for the macroscopic wave function. We compare contribution of the radiation damping with weakly (or semi-) relativistic effects appearing in the second-order on [Formula: see text]. The radiation damping appears in the third-order on [Formula: see text]. So it might be smaller than weakly relativistic effects, but it gives damping of the Langmuir waves which can be considerable.
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19

Wang, Zhiguo, Xiang Peng, Rui Zhang, Hui Luo, and Hong Guo. "“Radiation Damping” in gas spin comagnetometers." Journal of Magnetic Resonance 302 (May 2019): 14–20. http://dx.doi.org/10.1016/j.jmr.2019.03.004.

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20

Krishnan, V. V. "Radiation damping in microcoil NMR probes." Journal of Magnetic Resonance 179, no. 2 (April 2006): 294–98. http://dx.doi.org/10.1016/j.jmr.2005.12.011.

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21

Barone, P. M. V. B., and A. C. R. Mendes. "Lagrangian description of the radiation damping." Physics Letters A 364, no. 6 (May 2007): 438–40. http://dx.doi.org/10.1016/j.physleta.2006.12.037.

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22

Stump, Daniel R., and Gerald L. Pollack. "Magnetic dipole oscillations and radiation damping." American Journal of Physics 65, no. 1 (January 1997): 81–87. http://dx.doi.org/10.1119/1.18523.

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23

Wang, G., H. Li, Y. F. Shen, X. Z. Yuan, and J. Zi. "Anti-damping effect of radiation reaction." Physica Scripta 81, no. 1 (January 2010): 015403. http://dx.doi.org/10.1088/0031-8949/81/01/015403.

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24

Dahmen, Christian, Benjamin Schmidt, and Gero von Plessen. "Radiation Damping in Metal Nanoparticle Pairs." Nano Letters 7, no. 2 (February 2007): 318–22. http://dx.doi.org/10.1021/nl062377u.

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25

HUSSEIN, M. S., M. P. PATO, and J. C. WELLS. "CAUSAL CLASSICAL THEORY OF RADIATION DAMPING." Modern Physics Letters A 17, no. 25 (August 20, 2002): 1635–42. http://dx.doi.org/10.1142/s021773230200806x.

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It is shown how initial conditions can be appropriately defined for the integration of Lorentz–Dirac equations of motion. The integration is performed forward in time. The theory is applied to the case of the motion of an electron in an intense laser pulse, relevant to nonlinear Compton scattering.
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26

Bernui, Armando. "Radiation damping in closed expanding universes." Annalen der Physik 506, no. 5 (1994): 408–21. http://dx.doi.org/10.1002/andp.19945060506.

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27

Khrapko, Radi I. "Radiation damping of a rotating dipole." Optik 203 (February 2020): 164021. http://dx.doi.org/10.1016/j.ijleo.2019.164021.

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28

Trinks, C., and P. Ruge. "Fractional calculus applied to radiation damping." PAMM 2, no. 1 (March 2003): 266–67. http://dx.doi.org/10.1002/pamm.200310118.

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29

RAJU, SUVRAT, and C. K. RAJU. "RADIATIVE DAMPING AND FUNCTIONAL DIFFERENTIAL EQUATIONS." Modern Physics Letters A 26, no. 35 (November 20, 2011): 2627–38. http://dx.doi.org/10.1142/s021773231103698x.

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We propose a general technique to solve the classical many-body problem with radiative damping. We modify the short-distance structure of Maxwell electrodynamics. This allows us to avoid runaway solutions as if we had a covariant model of extended particles. The resulting equations of motion are functional differential equations (FDEs) rather than ordinary differential equations (ODEs). Using recently developed numerical techniques for stiff, retarded FDEs, we solve these equations for the one-body central force problem with radiative damping. Our results indicate that locally the magnitude of radiation damping may be well approximated by the standard third-order expression but the global properties of our solutions are dramatically different. We comment on the two-body problem and applications to quantum field theory and quantum mechanics.
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30

Zheng, Wei Guang, Ying Feng Lei, Qi Bai Huang, and Chuan Bing Li. "Topology Optimization of Applied Damping Material for Noise Control." Advanced Materials Research 629 (December 2012): 530–35. http://dx.doi.org/10.4028/www.scientific.net/amr.629.530.

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Applied damping material (ADM) is today widely used to reduce vibrations and sound radiations by damping out the resonant peaks of structures. The efficient use of ADM becomes more and more important from an optimization design view. In this paper, the potential of using topology optimization as a design tool to optimize the distribution of ADM on a vibrating plate to minimize its sound radiation is investigated. A solid isotropic material with penalization model is described based on a special interface finite element modeling for viscoelastic layer. Numerical analysis has been applied to demonstrate the validation of the proposed approach and shows that significant reductions of the sound radiation powers over a broadband frequency range are achieved by the optimized results.
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31

Williamson, David C., Johanna Närväinen, Penny L. Hubbard, Risto A. Kauppinen, and Gareth A. Morris. "Effects of radiation damping on Z-spectra." Journal of Magnetic Resonance 183, no. 2 (December 2006): 203–12. http://dx.doi.org/10.1016/j.jmr.2006.08.011.

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32

Deng, Aihua, Kazuhisa Nakajima, Xiaomei Zhang, Haiyang Lu, Baifei Shen, Jiansheng Liu, Ruxin Li, and Zhizhan Xu. "Betatron radiation damping in laser plasma acceleration." Laser and Particle Beams 30, no. 2 (April 17, 2012): 281–89. http://dx.doi.org/10.1017/s0263034612000079.

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AbstractWe explore the feasibility of accelerating electron beams up to energies much beyond 1 TeV in a realistic scale and evolution of the beam qualities such as emittance and energy spread at the final beam energy on the order of 100 TeV, using the newly formulated coupled equations describing the beam dynamics and radiative damping of electrons. As an example, we present a design for a 100 TeV laser-plasma accelerator in the operating plasma density np = 1015 cm−3 and numerical solutions for evolution of the normalized emittance as well as their analytical solutions. We show that the betatron radiative damping causes very small normalized emittance that promises future applications for the high-energy frontier physics.
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33

Petrosky, T. "Stochastic Maxwell-Lorentz equation in radiation damping." International Journal of Quantum Chemistry 98, no. 2 (2004): 103–11. http://dx.doi.org/10.1002/qua.10832.

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34

Spratt, Kyle S., Kevin M. Lee, Preston S. Wilson, Mark S. Wochner, and Mark F. Hamilton. "Radiation damping of an arbitrarily shaped bubble." Journal of the Acoustical Society of America 137, no. 4 (April 2015): 2254. http://dx.doi.org/10.1121/1.4920221.

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35

KOGA, JAMES, TIMUR ZH ESIRKEPOV, and SERGEI V. BULANOV. "Nonlinear Thomson scattering with strong radiation damping." Journal of Plasma Physics 72, no. 06 (December 2006): 1315. http://dx.doi.org/10.1017/s0022377806005708.

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36

Sodickson, A., W. E. Maas, and D. G. Cory. "The Initiation of Radiation Damping by Noise." Journal of Magnetic Resonance, Series B 110, no. 3 (March 1996): 298–303. http://dx.doi.org/10.1006/jmrb.1996.0046.

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37

Mao, Xi-An, and Chao-Hui Ye. "Understanding radiation damping in a simple way." Concepts in Magnetic Resonance 9, no. 3 (1997): 173–87. http://dx.doi.org/10.1002/(sici)1099-0534(1997)9:3<173::aid-cmr4>3.0.co;2-w.

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38

Berman, Gennady P., Michelle A. Espy, Vyacheslav N. Gorshkov, Vladimir I. Tsifrinovich, and Petr L. Volegov. "Radiation damping for speeding-up NMR applications." Concepts in Magnetic Resonance Part A 40A, no. 4 (August 2012): 179–85. http://dx.doi.org/10.1002/cmr.a.21237.

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39

Devkota, Tuphan, Brendan S. Brown, Gary Beane, Kuai Yu, and Gregory V. Hartland. "Making waves: Radiation damping in metallic nanostructures." Journal of Chemical Physics 151, no. 8 (August 28, 2019): 080901. http://dx.doi.org/10.1063/1.5117230.

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40

Castrigiano, D. P. L., and N. Kokiantonis. "Radiation damping of a quantum harmonic oscillator." Journal of Physics A: Mathematical and General 20, no. 13 (September 11, 1987): 4237–45. http://dx.doi.org/10.1088/0305-4470/20/13/027.

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41

Olmos, Bertha, José Manuel Jara, and Guillermo Martínez. "Radiation damping for rigid foundations. Approximate expressions." Vibroengineering PROCEDIA 27 (September 30, 2019): 103–8. http://dx.doi.org/10.21595/vp.2019.20913.

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42

Liao, Guojiang. "Damping property of MRE under gamma radiation." Abstracts of ATEM : International Conference on Advanced Technology in Experimental Mechanics : Asian Conference on Experimental Mechanics 2019 (2019): 1010B1015. http://dx.doi.org/10.1299/jsmeatem.2019.1010b1015.

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43

Wu, Jin-Hui, SAR Horsley, M. Artoni, and GC La Rocca. "Radiation damping optical enhancement in cold atoms." Light: Science & Applications 2, no. 2 (February 2013): e54-e54. http://dx.doi.org/10.1038/lsa.2013.10.

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44

Kunze, M., and A. D. Rendall. "The Vlasov-Poisson System with Radiation Damping." Annales Henri Poincaré 2, no. 5 (October 2001): 857–86. http://dx.doi.org/10.1007/s00023-001-8596-z.

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45

Mao, Xi-an, Dong-hui Wu, and Chao-hui Ye. "Radiation damping effects on NMR signal intensities." Chemical Physics Letters 204, no. 1-2 (March 1993): 123–27. http://dx.doi.org/10.1016/0009-2614(93)85615-u.

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46

Barbara, Thomas M. "Integration of bloch's equations with radiation damping." Journal of Magnetic Resonance (1969) 98, no. 3 (July 1992): 608–10. http://dx.doi.org/10.1016/0022-2364(92)90013-w.

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47

Björnsson, C. I. "Radiation Damping and the Two Mode Behavior in Pulsars." International Astronomical Union Colloquium 128 (1992): 391–93. http://dx.doi.org/10.1017/s000273160015560x.

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AbstractIt is argued that both observations and theory indicate that radiation damping plays an important rôle in pulsar emission. The two-mode behavior as well as the observed value of the brightness temperature can both be understood as a result of radiation damping. In this context, a possible cause for the enhanced depolarization in the wings of pulsar profiles is discussed.
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48

Givens, Michael J., George Mylonakis, and Jonathan P. Stewart. "Modular Analytical Solutions for Foundation Damping in Soil-Structure Interaction Applications." Earthquake Spectra 32, no. 3 (August 2016): 1749–68. http://dx.doi.org/10.1193/071115eqs112m.

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Foundation damping incorporates combined effects of energy loss from waves propagating away from a vibrating foundation (radiation damping) and hysteretic action in supporting soil (material damping). Foundation damping appears in analysis and design guidelines for force- and displacement-based analysis of seismic building response (ASCE-7, ASCE-41), typically in graphical form (without predictive equations). We derive closed-form expressions for foundation damping of a flexible-based single degree-of-freedom oscillator from first principles. The expressions are modular in that structure and foundation stiffness terms, along with radiation and hysteretic damping ratios, appear as variables. Assumptions inherent to our derivation have been employed previously, but the present results are differentiated by: (1) the modular nature of the expressions; (2) clearly articulated differences regarding alternate bases for the derivations and their effects on computed damping; and (3) completeness of the derivations. Resulting expressions indicate well-known dependencies of foundation damping on soil-to-structure stiffness ratio, structure aspect ratio, and soil damping. We recommend a preferred expression based on the relative rigor of its derivation.
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49

Oh, J., M. Ruzzene, and A. Baz. "Passive Control of the Vibration and Sound Radiation from Submerged Shells." Journal of Vibration and Control 8, no. 4 (April 2002): 425–45. http://dx.doi.org/10.1177/107754602023689.

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Vibration and noise radiation from fluid-loaded cylindrical shells are controlled using multiple stiffeners and Passive Constrained Layer Damping treatment. Dynamic and fluid finite element models are developed to study the fundamental phenomena governing the interaction between the stiffened shell, with and without damping, and the fluid domain surrounding it. The models are used to predict the response of the shell and to evaluate the effect of the stiffening rings and damping treatment on both the structural vibration and noise radiation in the fluid domain. The prediction of the models are validated experimentally and against the predictions of a commercial FE software package (ANSYS). It is shown that stiffening of the shell reduces the amplitude of the vibration and noise radiation, particularly for high order lobar modes. The attenuation of the shell response and sound radiation can be significantly increased through the application of Passive Constrained Layer Damping treatment on the inner surface of the stiffening rings. The numerical and experimental validations demonstrate the accuracy of the developed models and emphasize its potential extension to the application of smart materials for active control of vibration and noise radiation from fluid-loaded shells.
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50

Arquez, Sair, Rubén Cordero, and Hugo García-Compeán. "Radiation damping of a Yang–Mills particle revisited." Canadian Journal of Physics 98, no. 12 (December 2020): 1091–107. http://dx.doi.org/10.1139/cjp-2019-0389.

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The problem of a colour-charged point particle interacting with a four-dimensional Yang–Mills gauge theory is revisited. The radiation damping is obtained inspired in Dirac’s computation. The difficulties in the non-abelian case were solved by using an ansatz for the Liénard–Wiechert potentials already used in the literature (Ö. Sarıoğlu. Phys. Rev. D, 66, 085005 (2002). doi: 10.1103/PhysRevD.66.085005 ) for finding solutions to the Yang–Mills equations. Three non-trivial examples of radiation damping for a non-abelian particle are discussed in detail.
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